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Red cell membrane ATPase: Radiation inactivation estimates of “size”
Vol. 23, No. 2, 1966
BIOCHEMICAL
RED CELL MEMBRANE ATPase:
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RADIATION
INACTIVATION
GORDON R. KEPNER** and ROBERT I, Department
of Physiology,
Received
March
been reported
system the
quantitative
enzymatic
"target
"equivalent
molecular
and ouabain
insensitive
Materials
(collected
paper
ghosts.
an inactivation weight" ATPase
system
1 x lo6
enzyme
suggests
that
mechanism
ATPase
on
of
conventional
preparation,
the
of -1.5
x 10 -1acm3
for
the ouabain
both
that
experiments
sensitive
to this
volume
of-
of this
describes
Assuming
can be applied
The
the transport
of the Na, K, ouabain
with
an
sensitive
systems.
membranes
were
prepared
in ACD) by a modification
1mM NaH2P04,
et.
al.
1960.
Cells
solutions
and finally were
20 min.
adjusted at 20,000
from
were
hemolysed
washed
washed twice
to pH 7.5 with
Fellow:
Group
in Biophysics
202
et,
al.
in (6m~ Na2HP04, in
(1QmM Tris,
HCl or NaOH.
x g in a refrigerated
human blood
of Dodge,
and stored
by NSF GB 1928
NIH Predoctoral
fresh,
of the methods
1mM EDTA, 1mM glycylglycine),
1mM glycylglycine),
**
This
ior
has
preparations.
transport
as a marker
1964).
1946)
ghost
1963 and Post,
*Supported
of the Na-K active
activity
and Methods
Fragmented
for
the kinetics
(Skou,
(Lea,
suggest
were
between
human erythrocyte
experiments
All
correlation
inactivation
theory"
ATPase
membrane
can serve
fragments
sensitive
of cellular
activity
the radiation
ouabain
variety
and the kinetics
freeze-dried
California
stimulated,
in a wide
in membrane
of California
23, 1966
Sodium-Potassium
striking
OF "SIZE"*
MACEY
University
Berkeley,
ESTIMATES
centrifuge
in
1mN EDTA,
(1omM Tris).
Centrifuge (2-4'C).
runs
Vol. 23, No. 2, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
--Results FIG. ATPase
1
INACTIVATION
TOTAL
I .2
.Ol 0
I .4
I .6
DOSE
Each data fitted
point
to a single
Weighting
had no significant in the plot, calculated
represents
effect
on the calculated
lo5
I
1.4
using
a least
squares
according slopes.
megarads
Data were
for
procedure.
to their
Although the total
variances
not
included
ATPase
was on the
line.
frozen
Once dried, dried
I 1.2
or inversely
at three
Two ml of suspension quickly
I 1.0
by computer
equally
point
I .s
- Megarads
points
the data
ACTIVITY
fram 4 to 18 experiments.
exponential
the data
ATPare
ghosts
was pipetted
in a dry-ice
preparations were
;Xoentgen/minute
bath, remained
irradiated (in
with
air , &6OC)
into
and dried stable
a 25ml Erlenmeyer in a Virtis
and active
7.5 Mev electrons with
203
an electron
flask
vacuum
for
weeks,
system. Freeze-
at a dose rate linear
of
accelerator.
Vol.
23, No.
2, 1966
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
TABLE 1 *
Calculations
from
the data
of figure
1
ATPase Activity
v 0 x lo5
TOTAL
.12 + .01*
1.50
1
OUABAIN INSENS.
.13 + .Ol
1.65
1.1
OUABAIN SENS.
.12 + .Ol
1.50
1
*
Equations
1)
Jr*
V x 1018cm3
"Equiv.
M. Wt."
x 10
-6
used:
activity
= e-'
e D
V = inactivation
volume
0 = conversion
factor
cm3 = p gm/cm3x 1.6
lo-l2
x
lOOergs/gm-rad ergs/ev
x 85 ev Xctivating
event
D = Dose rads 2, **
P= density
***
glass Ghosts
'Three
chips
preparation:
were
(Bausch assayed
ml of incubation
was added shaker.
for
assumed = 1,d
ATPase
medium
to each flask
insensitive
ATPase
(5mM Tris,
stopped
NaCl,
at 37'C for
after
one hour
204
of ouabain
irradiation.
20mM KCl,
20 minutes
pH 7.4) in a Dubnoff EDTA, MgC12)
by addition
of Dreisbach,
by duplicating
The addition
after
(&nM each of Na2-ATP,
the method
was determined
the dosimetry.
a few hours 115mM
suspension
following
of 10w5M ouabain.
used for
activity
and incubated
and the reaction
P1 was measured
presence
weight"
and Lomb) were
One ml of substrate
was added TCA.
of dried
molecular
= .Ol
+ 2u
Cobalt
= "equivalent
7 v Navog.
of 2ml of 18%
1965.
the above assay at this
Cuabain in
the
concentration
Vol. 23, No. 2, 1966
gave ATPase the
BIOCHEMICAL
values
incubation
between
similar
and reaction
the
ATPase.
very
total
control
ghosts
insensitive
fia-K
Ghost
was less
(calibrated
with
for
ATPase
ATPase
suspension
BSA) gave
when K was omitted we identify
insensitive
activated
.l% that
than
obtained
Accordingly,
media.
values
for
ATPase.
themeoglobin)
to those
and the ouabain
Typical
freeze-dried
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the difference
as the Na-K stimulated
activities
were:
25pg Pi/hr./ml
ATPase
and 8&g P,/hr./ml
for
hemoglobin
(determined
by cyanme-
of whole
"protein"
from
values
blood
ouabain
and the Biuret
&mg/ml
reagent
ghosts.
--Discussion Kadiation molecular
inactivation
weight
of dried
of macromolecules Haanen,
et.
a)
Inactivation
of indirect
of
to those
The energy
secondary
released
inactivating
1961) al.
and
1966;
to biological
(Augenstein,
1963;
Brustad,
in the material
to the separation inactivations
between
and the
initial
is minimtzed
if
ionizing the
specimen
irradiation. biological within
in the initfal
if
et. theory
distributed
occurring
is highly
function
per
during
ionizations
ionizations
the biological
of target
the highly-specific
released
(Alper,
the
include:
compared
state
and Pollard,
of assumptions
are randomly
small
in a dehydrated
due only c)
these
The effect
(Hutchinson preparations
on a number
is
been used to estimate
The application
events
volume
events.
b)
rests
Inactivating
target
is
1965).
In particular
1962),.
enzymes
in biological
al.
preparations
has frequently
occurs
event
is
the
ionizing
localized
it
function target
event
assumed
target
is
volume.
and the ensuing
and sufficient
in the
assayed
to inactivate
volume.
to be ~~70-100
The energy ev (Hutchinson,
1965) ,, The presence excitations the energy
leading release
of impurities,
the possibility
to thermal
inactivations,
in the target
volume
205
of radiation-induced and the errors
result
in
a significant
in estimating degree
Vol.
23,
No.
2, 1966
BIOCHEMICAL
of uncertainty
as to the results
has suggested factor
the method
that
of 2-3 of the
countered
(Hutchinson
the basis
for
"true
imply
that
data
could
of figure
to a single
also
from ATPase
systems
steps
would
correspond
target
arranged
inactivate
two interpretations
II)
en-
to improve
does not
molecular
species.
The
Inactivation
coupled of any one
Our calculated
of the entire
The appearance
necessarily
of a tightly
sequence.
of the molecular
single
This
consisting
volume
the
sequence
of parallel
slopes
configuration
of the
volumes.
The two ATPase
inactivation
a
and to investigate
with
in series.
to the inactivation
inactivation
sometimes
preparation
theory.
the entire
may have one or many steps.
ATPase
work
to within
in progress
1 correspond
corresponds
steps
suggests
on this
each ATPase result
are
Work is
from one-hit
of these
I)
1961).
weight
errors
predicted
of biochemical
which
larger
Other
in membranes.
curves
sequence
volumes
but
COMMUNICATIONS
technique.
the molecular
the results
mechanisms
RESEARCH
hy this
estimates
and Pollard,
The inactivation
BIOPHYSICAL
obtained
value";
interpreting
radio-biological
exponential
AND
sites
event
in
The two ATPases
occur
in a single
the volume have
inactivation
inactivates
separate
but
both
equal
volume.
An
enzyme functions.
inactivation
volumes.
Acknowledgements The expert acknowledged. in providing critical
technical
contribution
The authors
appreciate
accelerator comments
time
of Mr.
Doug Pounds
the kindness
and thank
Dr.
Ernest
is
gratefully
of Dr.
C.A.
Tobias
Dobson
for
valuable
on the manuscript.
References Alper,
T., Haig, D. and M. Clarke, Biochem. Biophys. Res. Commun., 2, (1966). Augenstein, L., Progr. Biophys. Biophys. Chem., l3, 3, (1963). Brustad, T., Advan. Med. Phys., g, 161, (1962). C. and D. Hanahan, Arch. Biochem, Biophys., 100, Dodge, J., Mitchell, (1963).
206
278,
119,
Vol. 23, Neo. 2, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Dreisbach, R., Anal. Biochem., l.0, 169, (1965). Haanen, C., Morselt, G., Schoenmakers, J., Maters, M. and R. Braams, Stand. J. Haematol., 2, 248, (1965). F. in 18th Symp. Fund. Can. Res. Anderson Hosp. & Tumor Inst., Hutchinson, Cellular Radiation Biology, Williams & Wilkins Co., Baltimore, (1965). Hutchinson, F. and E. Pollard, Mechanisms in Radiobiology, 1, 71, Academic Press, New York and London, (1961). Lea, D., Actions of Radiations on Living Cells, Macmillan, London, (1946). Post, R., Merrit, C., Kinsolving, C. and C. Albright, J. Biol. Chem., 235, 1796, (1960). Skou, J., Progr. Biophys. Biophys. Chem., l.4, 131, (1964).
207
BIOCHEMICAL
RED CELL MEMBRANE ATPase:
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RADIATION
INACTIVATION
GORDON R. KEPNER** and ROBERT I, Department
of Physiology,
Received
March
been reported
system the
quantitative
enzymatic
"target
"equivalent
molecular
and ouabain
insensitive
Materials
(collected
paper
ghosts.
an inactivation weight" ATPase
system
1 x lo6
enzyme
suggests
that
mechanism
ATPase
on
of
conventional
preparation,
the
of -1.5
x 10 -1acm3
for
the ouabain
both
that
experiments
sensitive
to this
volume
of-
of this
describes
Assuming
can be applied
The
the transport
of the Na, K, ouabain
with
an
sensitive
systems.
membranes
were
prepared
in ACD) by a modification
1mM NaH2P04,
et.
al.
1960.
Cells
solutions
and finally were
20 min.
adjusted at 20,000
from
were
hemolysed
washed
washed twice
to pH 7.5 with
Fellow:
Group
in Biophysics
202
et,
al.
in (6m~ Na2HP04, in
(1QmM Tris,
HCl or NaOH.
x g in a refrigerated
human blood
of Dodge,
and stored
by NSF GB 1928
NIH Predoctoral
fresh,
of the methods
1mM EDTA, 1mM glycylglycine),
1mM glycylglycine),
**
This
ior
has
preparations.
transport
as a marker
1964).
1946)
ghost
1963 and Post,
*Supported
of the Na-K active
activity
and Methods
Fragmented
for
the kinetics
(Skou,
(Lea,
suggest
were
between
human erythrocyte
experiments
All
correlation
inactivation
theory"
ATPase
membrane
can serve
fragments
sensitive
of cellular
activity
the radiation
ouabain
variety
and the kinetics
freeze-dried
California
stimulated,
in a wide
in membrane
of California
23, 1966
Sodium-Potassium
striking
OF "SIZE"*
MACEY
University
Berkeley,
ESTIMATES
centrifuge
in
1mN EDTA,
(1omM Tris).
Centrifuge (2-4'C).
runs
Vol. 23, No. 2, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
--Results FIG. ATPase
1
INACTIVATION
TOTAL
I .2
.Ol 0
I .4
I .6
DOSE
Each data fitted
point
to a single
Weighting
had no significant in the plot, calculated
represents
effect
on the calculated
lo5
I
1.4
using
a least
squares
according slopes.
megarads
Data were
for
procedure.
to their
Although the total
variances
not
included
ATPase
was on the
line.
frozen
Once dried, dried
I 1.2
or inversely
at three
Two ml of suspension quickly
I 1.0
by computer
equally
point
I .s
- Megarads
points
the data
ACTIVITY
fram 4 to 18 experiments.
exponential
the data
ATPare
ghosts
was pipetted
in a dry-ice
preparations were
;Xoentgen/minute
bath, remained
irradiated (in
with
air , &6OC)
into
and dried stable
a 25ml Erlenmeyer in a Virtis
and active
7.5 Mev electrons with
203
an electron
flask
vacuum
for
weeks,
system. Freeze-
at a dose rate linear
of
accelerator.
Vol.
23, No.
2, 1966
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
TABLE 1 *
Calculations
from
the data
of figure
1
ATPase Activity
v 0 x lo5
TOTAL
.12 + .01*
1.50
1
OUABAIN INSENS.
.13 + .Ol
1.65
1.1
OUABAIN SENS.
.12 + .Ol
1.50
1
*
Equations
1)
Jr*
V x 1018cm3
"Equiv.
M. Wt."
x 10
-6
used:
activity
= e-'
e D
V = inactivation
volume
0 = conversion
factor
cm3 = p gm/cm3x 1.6
lo-l2
x
lOOergs/gm-rad ergs/ev
x 85 ev Xctivating
event
D = Dose rads 2, **
P= density
***
glass Ghosts
'Three
chips
preparation:
were
(Bausch assayed
ml of incubation
was added shaker.
for
assumed = 1,d
ATPase
medium
to each flask
insensitive
ATPase
(5mM Tris,
stopped
NaCl,
at 37'C for
after
one hour
204
of ouabain
irradiation.
20mM KCl,
20 minutes
pH 7.4) in a Dubnoff EDTA, MgC12)
by addition
of Dreisbach,
by duplicating
The addition
after
(&nM each of Na2-ATP,
the method
was determined
the dosimetry.
a few hours 115mM
suspension
following
of 10w5M ouabain.
used for
activity
and incubated
and the reaction
P1 was measured
presence
weight"
and Lomb) were
One ml of substrate
was added TCA.
of dried
molecular
= .Ol
+ 2u
Cobalt
= "equivalent
7 v Navog.
of 2ml of 18%
1965.
the above assay at this
Cuabain in
the
concentration
Vol. 23, No. 2, 1966
gave ATPase the
BIOCHEMICAL
values
incubation
between
similar
and reaction
the
ATPase.
very
total
control
ghosts
insensitive
fia-K
Ghost
was less
(calibrated
with
for
ATPase
ATPase
suspension
BSA) gave
when K was omitted we identify
insensitive
activated
.l% that
than
obtained
Accordingly,
media.
values
for
ATPase.
themeoglobin)
to those
and the ouabain
Typical
freeze-dried
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the difference
as the Na-K stimulated
activities
were:
25pg Pi/hr./ml
ATPase
and 8&g P,/hr./ml
for
hemoglobin
(determined
by cyanme-
of whole
"protein"
from
values
blood
ouabain
and the Biuret
&mg/ml
reagent
ghosts.
--Discussion Kadiation molecular
inactivation
weight
of dried
of macromolecules Haanen,
et.
a)
Inactivation
of indirect
of
to those
The energy
secondary
released
inactivating
1961) al.
and
1966;
to biological
(Augenstein,
1963;
Brustad,
in the material
to the separation inactivations
between
and the
initial
is minimtzed
if
ionizing the
specimen
irradiation. biological within
in the initfal
if
et. theory
distributed
occurring
is highly
function
per
during
ionizations
ionizations
the biological
of target
the highly-specific
released
(Alper,
the
include:
compared
state
and Pollard,
of assumptions
are randomly
small
in a dehydrated
due only c)
these
The effect
(Hutchinson preparations
on a number
is
been used to estimate
The application
events
volume
events.
b)
rests
Inactivating
target
is
1965).
In particular
1962),.
enzymes
in biological
al.
preparations
has frequently
occurs
event
is
the
ionizing
localized
it
function target
event
assumed
target
is
volume.
and the ensuing
and sufficient
in the
assayed
to inactivate
volume.
to be ~~70-100
The energy ev (Hutchinson,
1965) ,, The presence excitations the energy
leading release
of impurities,
the possibility
to thermal
inactivations,
in the target
volume
205
of radiation-induced and the errors
result
in
a significant
in estimating degree
Vol.
23,
No.
2, 1966
BIOCHEMICAL
of uncertainty
as to the results
has suggested factor
the method
that
of 2-3 of the
countered
(Hutchinson
the basis
for
"true
imply
that
data
could
of figure
to a single
also
from ATPase
systems
steps
would
correspond
target
arranged
inactivate
two interpretations
II)
en-
to improve
does not
molecular
species.
The
Inactivation
coupled of any one
Our calculated
of the entire
The appearance
necessarily
of a tightly
sequence.
of the molecular
single
This
consisting
volume
the
sequence
of parallel
slopes
configuration
of the
volumes.
The two ATPase
inactivation
a
and to investigate
with
in series.
to the inactivation
inactivation
sometimes
preparation
theory.
the entire
may have one or many steps.
ATPase
work
to within
in progress
1 correspond
corresponds
steps
suggests
on this
each ATPase result
are
Work is
from one-hit
of these
I)
1961).
weight
errors
predicted
of biochemical
which
larger
Other
in membranes.
curves
sequence
volumes
but
COMMUNICATIONS
technique.
the molecular
the results
mechanisms
RESEARCH
hy this
estimates
and Pollard,
The inactivation
BIOPHYSICAL
obtained
value";
interpreting
radio-biological
exponential
AND
sites
event
in
The two ATPases
occur
in a single
the volume have
inactivation
inactivates
separate
but
both
equal
volume.
An
enzyme functions.
inactivation
volumes.
Acknowledgements The expert acknowledged. in providing critical
technical
contribution
The authors
appreciate
accelerator comments
time
of Mr.
Doug Pounds
the kindness
and thank
Dr.
Ernest
is
gratefully
of Dr.
C.A.
Tobias
Dobson
for
valuable
on the manuscript.
References Alper,
T., Haig, D. and M. Clarke, Biochem. Biophys. Res. Commun., 2, (1966). Augenstein, L., Progr. Biophys. Biophys. Chem., l3, 3, (1963). Brustad, T., Advan. Med. Phys., g, 161, (1962). C. and D. Hanahan, Arch. Biochem, Biophys., 100, Dodge, J., Mitchell, (1963).
206
278,
119,
Vol. 23, Neo. 2, 1966
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Dreisbach, R., Anal. Biochem., l.0, 169, (1965). Haanen, C., Morselt, G., Schoenmakers, J., Maters, M. and R. Braams, Stand. J. Haematol., 2, 248, (1965). F. in 18th Symp. Fund. Can. Res. Anderson Hosp. & Tumor Inst., Hutchinson, Cellular Radiation Biology, Williams & Wilkins Co., Baltimore, (1965). Hutchinson, F. and E. Pollard, Mechanisms in Radiobiology, 1, 71, Academic Press, New York and London, (1961). Lea, D., Actions of Radiations on Living Cells, Macmillan, London, (1946). Post, R., Merrit, C., Kinsolving, C. and C. Albright, J. Biol. Chem., 235, 1796, (1960). Skou, J., Progr. Biophys. Biophys. Chem., l.4, 131, (1964).
207